US3318989A

US3318989A - Method for melt-spinning of filamentary articles

Info

Publication number: US3318989A
Application number: US466429A
Authority: US
Inventors: Sato Toru; Katsuyama Shigeo; Sasaki Toshio
Original assignee: Individual
Current assignee: Asahi Kasei Corp; Asahi Chemical Industry Co Ltd
Priority date: 1964-07-03
Filing date: 1965-06-23
Publication date: 1967-05-09
Anticipated expiration: 1984-05-09
Also published as: CH437619A; GB1075777A; DE1494548A1; FR1439568A

Description

United States Patent Office A 3 ,318,989 Patented May 9, 1967 3,318,989 METHOD FOR MELT-SPINNING F FILAMENTARY ARTICLES Toru Sato, higeo Katsuyama, and Toshio Sasaki, Nobeoka-shi, Japan, assignors to Asahi Kasei Kogyo Kabushiki Kaisha, Osaka, Japan, a corporation of Japan No Drawing. Filed June 23, 1965, Ser. No. 466,42?

Claims priority, application Japan, July 3, 1964, 39/37,554; July 4, 1964, 39/357,266 6 Claims. (Cl. 264-176) This invention relates to a method for producing filamentary articles from heat-meltable polymers having fiber forming ability. In one aspect, this invention relates to a method for producing filamentary articles having superior transparency from polyamide.

The filamentary articles dealt with in the present invention include monofilaments, multifilaments, films, ribbons, strands, and the like. Also, heat meltable polymers cover polyamide, polyvinyl chloride, polypropylene, polyethylene, polyester, and the like.

Filamentary articles of heat-meltable polymers are generally produced by extruding from spinnerets melted polymers to form into filamentary shape and cooling and solidifying extrudates by a cooling medium. As such a cooling medium, various materials i.e., various kinds of liquid including mercury and various kinds of gaseous substances have been hereto-fore used. Among liquid mediums, Water has been most popularly used as an inert medium. However, when substances such as polyamide and the like in heated or melted state contact with water, they are affected by water, advancing in crystallinity and falling in transparency and lustre. This renders not only the stretching at room temperature difficult but also the surface structure of filamentary articles rough at stretching time. When non-polar solvents are used, they are liable to adhere to or be adsorbed by the filamentary articles due to the difficulty of removal in the subsequent process. The use of mercury as a cooling medium is a health hazard for the workers. When a gaseous substance is used as a cooling medium, the cooling velocity is slow. Hence substances such as polyamide and the like are liable to be crystallized by the end of cooling, losing transparency and stretchability at room temperature. When filamentary articles of higher denier are to be cooled, an attempt to receive them on a drum or belt to effect cooling by contact with cold surfaces or cold gas has been proposed but this is not acceptable because of the slow cooling velocity. In such instances, substances such as polyamide or the like are not only subject to be crystallized, to deteriorate in transparency and lose stretchability at room temperature but in addition such drawbacks are presented as the difiiculty of increasing their spinning velocity and the liability of forming products of non-uniform cross-section which are caused by laying the articles directly on the drum or belt.

The above-mentioned drawbacks are completely overcome in accordance with the method of the present invention which comprises contacting heated or melted filamentary extrudate with, as a novel cooling medium, Na SO -10H O or a substance having a fairly similar effect, such as Na CO IOH O, or Na CO -7H O or Na S O -H O to cool and solidify the said extrudate.

In accordance with the present method, heated or melted filamentary substances of heat-meltable polymers having fiber forming ability and having been extruded from spinnerets are hung down upon fine particles of the above-mentioned compound which are laid on a revolving belt and always maintained in the band-like form of uniform thickness and thereafter are allowed to travel with the belt while maintaining the contact with the fine particles so as to be cooled and solidified. In an alternative method, the above-mentioned heated or melted filamentary substances are passed through a layer of fine particles of the above-mentioned compound to be cooled and solidified by the contact. In another alternative method, the above-mentioned heated or melted filamentary substances are passed through a slurry prepared by incorporating a certain amount of aqueous solution of the above-mentioned compounds into the respective compounds and cooling and solidifying are effected by the contact therewith.

After either of these methods, cooled filamentary articles are washed with water and Wound up on bobbins or the like or they may be subjected to various other treatments.

The reason Why heated or melted filamentary substances are cooled efficiently by the contact with the above-mentioned compound or its slurry lies in that it loses a part or all of its crystallization Water and absorbs a large amount of heat at temperatures higher than a definite point. For example Na SO -10H O liberates its crystallization Water at a temperature of 324 C. to absorb heat of 19.02 KCal and Na CO -l0H O liberates 3 mols of its crystallization water at a temperature of 32.1 C. to become Na CO -7H O, which liberates 6 mols of its crystallization water at a temperature of 353 C. to absorb heat of 18.42 KCal in total. The utilization of above-mentioned endothermic effects in the present process afford a quick cooling effect of higher cooling capacity compared with common cooling medium.

There are many compounds which liberate the crystallization Water e.g. CaCl -6H O, MgCl 6H O Zn(C10 -4H O, CdBr -4H O and the like, however, they have little commercial value as a cooling medium to be used for cooling and solidifying heated or melted filamentary e'xtrudates in the melt spinning process for the following reasons, (1) the temperatures at which they liberate crystallization water are too high to solidify said melted filamentary substances or the heat absorbed at the liberation is small, (2) the temperature at the liberation of crystallization Water is exceedingly low or efflorescence inclination are strong, (3) diliquescence inclinations are strong, (4) the contact with heated or melted substances cause not only the liberation of crystallization water but also chemical decomposition, (5) cohesive inclinations are strong and fluidity is low and agitation is difiicult at the state coexisting with aqueous solution, (6) they discolor filamentary articles, (7) their costs are high and the recovery of high efiiciency are required or (8) they cause extreme swelling or act to decompose filamentary articles.

The above-mentioned compounds freed from the crystallization water flow down while forming an aqueous solution or slurry with liberated water in which for the greater part they are dissolved or adhere to adjacent above-mentioned compound or to filamentary articles.

The separation of water naturally occurs from the contact part and separated water works efficiently toattain the object of cooling and solidifying While preventing the filamentary articles from deforming and being marred by virtue of its function as a lubricant. The remaining aqueous solution or aqueous solution adhering to adjacent above-mentioned compound makes the compound move readily and contact smoothly with heated or melted filamentary articles.

Since the heated or melted filamentary articles of heatmeltable polymer is quickly cooled and solidified, substances such as polyamide are less crystallized, and become easily stretchable at room temperature and superior in transparency.

Further it is a characteristic point of the present method a.) hat the influence of water is less since its cooling mechnism is entirely different from that of immers on-1n- Iater method. Furthermore since the cooling prmc1ple 1 the present invention does not merely rely on the com- 101] conduction brought about by the contact with liquid r gas but also most positively rely on the strong endoie-rmic effect at the time of liberating crystallization water nd since the amount of heat absorbed is large per unit eight of coolant, the cooling velocity is high and the :ngth of cooling apparatus is not required to be large. esides, there is no need of great care in controlling the :mperature of a cooling bath. So long as the cooling is arried out at temperatures lower than that at which a trge amount of compound containing crystallization water existing, a slight variation of temperature hardly causes rouble. This is also an important advantage.

The above-mentioned compounds or their aqueous soluon adhering to filamentary articles can be readily elimiated by washing with water.

Polymers capable of forming fibers to which the present iethod can be effectively applied include various kinds f polyamides, polyvinyl chloride, polypropylene, polythylene, polyester and the like.

The present invention may be more fully understood rom the following examples which are offered by way of .lustration and not by Way of limitation.

Example Polyamide (nylon 6) having been melted by heating t a temperature of 275 C. was extruded through a pinneret provided with 10 spinning orifices each having a iameter of 1.6 mm. and hung down and passed through piled layer of Na SO -10H O having a particle diamter of smaller than 0.3 mm. When the extruded filaients reached the depth of 40 cm., their travelling direcon was changed by a rod and they were further passed irough a piled layer of Na SO -10H O over a length of cm. and taken up at a velocity of 32 m./min. After eing washed with Water they were stretched 4.2 times as )ng as the original length at room temperature. Each f the resulting filamentary articles had a round crossaction of about 970 denier, a tenacity of 4.1 g./d. and an longation of 37 percent. They were superior in transarency and lustre compared with those cooled and solidied With water at a temperature of 20 C. and at the same ther conditions.

Example 2 Polyvinyl chloride having been melted by heating at temperature of 200 C. were extruded through a spineret provided with 10 spinning orifices each having a dimeter of 1.6 mm. and hung down upon a belt having a orizontal length of 200 cm., running at a velocity of 32 1./min. and on the surface of which Na CO -10H O aving a particle size smaller than 0.4 mm. was laid with uniform thickness of about 2 cm. At a point 20 cm. part from the suspension point, Na CO -10H O powder 'as overlaid upon the travelling filaments so as to form layer of about 1 cm. to cover a latter and at the point 80 cm. from the suspension point, the travelling filaients were separated from the belt. After being washed ith water, the filaments were stretched 3.8 times as long s the original length. Each of the resulting filaments ad a round cross-section of about 1200 denier, a tenacity f 2.2 g./d. and an elongation of 24 percent.

Example 3 Polyamide (nylon 6) having been melted by heating at temperature of 290 C. was extruded through a spineret provided with 6 spinning orifices each having a dimeter of 2.2 mm. and hung down and passed through a lurry at a temperature of 22 C. prepared by mixing arts by weight of Na SO -H O and one part by weight 1f water. When the extruded filaments reached the depth if 30 cm., their travelling direction was changed by use If a direction change roll. They were further passed through the slurry over a length of 40 cm. and taken up at a velocity of 33 tn/min. Thereafter they were washed with water and stretched 4.2 times as long as the original length. Each of the resulting filaments had a round crosssection of about 2000 denier, a tenacity of 4.3 g./d. and an elongation of 29.0 percent. Compared with filaments cooled and solidified with water at a temperature of 22 C. at the same other conditions, they had more superior transparency and lustre.

Example 4 Polypropylene having been melted by heating at a temperature of 265 C. was extruded through a spinneret provided with 20 spinning orifices each having a diameter of 1.2 mm. and hung down and passed through a slurry at a temperature of 15 C. prepared by mixing and stirring 10 parts by weight of Na S O -5H O and one part by weight of water. When the extruded filaments reached the depth of 30 cm., they were turned to travel in a different direction by a roll, passed through the slurry for a distance of 40 cm. and taken up at a velocity of 30 m./ min. After being washed with water, they were stretched 6.3 times as long as the original length at a temperature of 50 C. Each of the resulting filaments had a round cross-section of about 330 denier, a tenacity of 4.5 g./d. and an elongation of 17.0 percent.

Example 5 Polyethylene terephthalate having been melted by heating at a temperature of 300 C. was extruded through a spinneret provided with 20 spinning orifices each having a diameter of 1.2 mm. and hung down to pass through a slurry at a temperature of 30 C. prepared by mixing and stirring 16 parts by weight of Na SO -10I-I O and one part by Weight of water. When they reached the depth of 30 cm., they were turned to travel in a different direction by a roll. They were further passed through the slurry for a distance of 40 cm. and taken up at a velocity of 30 m./min. After being washed with water, they were stretched 3 times as long as the original length at a temperature of 70 C. and then 4.5 times the original length at a temperature of 150 C. Each of the resulting filaments had a round cross-section of about 550 denier, a tenacity of 3.9 g./d. and an elongation of 18.0 percent.

Example 6 High density polyethylene having been melted by heating at a temperature of 245 C. was extruded through a spinneret provided with 36 spinning orifices each having a diameter of 0.8 mm. and hung down to pass through a slurry at a temperature of 45 C. in temperature prepared by mixing and stirring 17 parts by weight of and one part by weight of water. When the extruded filaments reached the depth of 30 cm., they were turned to travel in a different direction by a roll, passed through the slurry for a distance of 40 cm. and taken up at a velocity of 25 m./min. After being washed with water, they were stretched 8.0 times as long as the original length at a temperature of 97 C. Each of the resulting filaments had a round cross-section of about 100 denier, a tenacity of 4.6 g./d. and an elongation of 40 percent.

Example 7 Polyamide (nylon 6) having been melted by heating at a temperature of 275 C. was extruded through a spinneret provided with 8 spinning orifices each having a diameter of 1.8 mm. and hung down to pass through a slurry at a temperature of 22 C. prepared by mixing and stirring 12 parts by Weight of Na S O -5H O and one part by weight of water. When the extruded filaments reached the depth of 30 cm., they were turned in a different direction by means of a roll and further passed through the slurry at a temperature of 40 cm. and taken up at a velocity of 35 m./ min. After being washed with water, they were stretched 4.2 times as long as the original length. Each of the resulting filaments had a round cross-section of about 1500 denier, a tenacity of 4.1 g./ d and an elongation of 32.0 percent. They were superior in transparency and lustre compared with those cooled and solidified with water at a temperature of 22 C. and at the same other conditions.

What is claimed is:

1. A method for producing filamentary articles of a polymer capable of forming fibers by melt extrusion which comprises contacting molten or hot filamentary extrudate of said polymers from spinnerets with a hydrate of an inorganic salt selected from the group of Na SO -H O, N-a CO -l0H O, N32C037H2O and Na S O '5H O, the filamentary extrudate being at a sulficiently elevated temperature to cause the salt to liberate at least a part of the water of crystallization to accentuate heat absorption whereby to obtain cooled and solidified filamentary articles.

2. A method for producing filamentary articles of polyamide which comprises contacting molten or hot filamentary extrudate of polyamide from spinnerets with Na SO -10H O the filamentary extrudate being at a sufficiently elevated temperature to cause the salt to liberate at least a part of the water of crystallization to accentuate heat absorption whereby to obtain cooled, and solidified filamentary articles of polyamide having superior transparency.

3. A method for producing filamentary articles of polyamide which comprises contacting molten or hot filamentary extrudate of polyamide from spinnerets with a hydrate of an inorganic salt selected from the group conslsting Of Na CO -10H O, N32CO3'7H20 and the filamentary extrudate being at a sufficiently elevated temperature to cause the salt to liberate at least a part of the water of crystallization to accentuate heat absorption whereby to obtain cooled and solidified polyamide having superior transparency.

4. A method for producing filamentary articles of polymers capable of forming fiber selected from the group of polyvinyl chloride, polypropylene, polyethylene and polyethylene terep'hthalate which comprises contacting molten or hot filamentary extrudate of the above mentioned polymer from spinnerets with Na SO l0H O, the filamentary extrudate being at a sufliciently elevated temperature to cause the salt to liberate at least a part of the water of crystallization to accentuate heat absorption whereby to obtain cooled and solidified filamentary articles of said polymers.

5. A method for producing filamentary articles of polymers capable of forming fiber selected from the group of polyvinyl chloride, polypropylene, polyethylene and polyethylene terephthalate which comprises contacting molten or hot filamentary extrudate of the above-mentioned polymer from spinnerets with a hydrate of an inorganic salt selected from the group of Na CO -10H O, Na CO -7H O and Na S O -SH O, the filamentary extrudate being at a sufficiently elevated temperature to cause the salt to liberate at least a part of the water of crystallization to accentuate heat absorption whereby to obtain cooled and solidified filamentary articles of said polymers.

6. A method as claimed in claim 1 wherein said obtained filamentary articles are washed with water to remove any adherent salt.

References Cited by the Examiner UNITED STATES PATENTS 2,034,008 3/1936 Taylor 26413l X 3,027,602 4/1962 Hamilton et al 264-l78 3,052,989 9/ 1962 Doleman.

3,061,941 11/1962 Goy et a1.

3,072,968 1/1963 \Vatson et a1.

3,104,937 9/1963 Wyckoff et a1 264178 3,242,528 3/1966 Elder.

3,264,389 8/1966 Sims 264-l76 X ALEXANDER H. BRODMERKEL, Primary Examiner.

J. H. WOO, Assistant Examiners.

Claims

1. A METHOD FOR PRODUCING FILAMENTARY ARTICLES OF A POLYMER CAPABLE OF FORMING FIBERS BY MELT EXTRUSION WHICH COMPRISES CONTACTING MOLTEN OR HOT FILAMENTARY EXTRUDATE OF SAID POLYMERS FROM SPINNERETS WITH A HYDRATE OF AN INORGANIC SALT SELECTED FROM THE GROUP OF NA2SO4$10H2O, NA2CO3$10H2O, NA2CO3$7H2O AND NA2S2O3$5H2O, THE FILAMENTARY EXTRUDATE BEING AT A SUFFICIENTLY ELEVATED TEMPERATURE TO CAUSE THE SALT TO LIBERATE AT LEAST A PART OF THE WATER OF CRYSTALLIZATION TO ACCENTUATE HEAT ABSORPTION WHEREBY TO OBTAIN COOLED AND SOLIDIFIED FILAMENTARY ARTICLES.